Browsing by Author "Klein, Bradley G."

Now showing 1 - 20 of 27
  • Thumbnail Image
    Age and Sex Related Behavioral Changes in Mice Congenitally Infected with Toxoplasma gondii: Role of dopamine and other neurotransmitters in the genesis of behavioral changes due to congenital infection and attempted amelioration with interferon gamma
    Goodwin, David G. (Virginia Tech, 2011-07-12)
    Evidence suggests that the neurotropic parasite Toxoplasma gondii may play a role in the development of cognitive impairments. My hypothesis was that congenital exposure to T. gondii would lead to detectable age and sex related differences in behavior and neurotransmitter levels in mice. The neurotransmitter dopamine and commonly used anti-schizophrenic agents were evaluated against T. gondii in human fibroblast cells. Dopamine caused a significant increase in tachyzoite numbers at 250 nM but not 100 nM and the drugs valproic acid, fluphenazine, thioridazine and trifluoperazine inhibited T. gondii development. The effects T. gondii infection had on behavior were examined using a congenital mouse model. Previous work demonstrated maternal immune stimulation (MIS) with interferon gamma (INF-g) resulted in decreased fetal mortality from congenital T. gondii infections; therefore I examined the effects of INF- g treatment of mothers to determine if protection from the behavioral effects of T. gondii occurred in their offspring. No differences in concentrations of neurotransmitters in the brains of congenitally infected mice were observed. I found that mice infected with T. gondii developed adult onset behavior impairments with decreased rate of learning, increased activity and decreased memory, indicating cognitive impairment for male mice and not female mice. My findings support the evidence T. gondii is a factor in the development of cognitive impairments. My results for T. gondii exposed male mice are consistent with the convention that males have more cognitive impairments in the prodromal stage of schizophrenia. MIS with IFN-g had a minimal effect on behavior post sexual maturity but had a greater effect on pre sexual maturity female mice which exhibited difficulties with spatial memory, coordination and the ability to process stimuli. The results indicate the behavior alterations from IFN- g are transient. When MIS is given prior to congenital infection with T. gondii, we detected no behavior deficits in any group of mice, including male mice post sexual maturity. Based on the results of my study, I must reject the hypothesis that neurotransmitter levels are influenced by congenital toxoplasmosis and accept the hypothesis that congenital T. gondii infection caused cognitive impairments in male mice post sexual maturity.
  • Thumbnail Image
    The Analgesic Effects of Epidural Ketamine in Dogs With a Chemically Induced Synovitis: A Comparison Between Pre - or Post - Injury Administration
    Hamilton, Stephanie Marie (Virginia Tech, 2003-05-05)
    The objective of this study was to determine if administering epidural ketamine before or after the induction of a sodium urate crystal synovitis provides analgesia in dogs. In Part I, sixteen dogs were anesthetized with propofol (4 mg kg-1 intravenously). A sodium urate crystal synovitis was induced in the right stifle and allowed to develop for 12 hours. These dogs were again anesthetized with propofol and an epidural injection at the lumbosacral space of either ketamine (2 mg kg-1) or placebo (saline containing not more than 0.1 mg ml-1 benzethonium chloride) was performed. Analgesia was measured with a force platform and a numerical rating scale (NRS). Assessments were performed before and at 12, 14, 16, 18, 20 and 24 hours after the induction of synovitis. Vertical ground reaction forces were significantly decreased and numerical rating scale scores of total pain were significantly increased after the induction of synovitis in all dogs (p<0.05). No significant differences in ground reaction forces or total pain scores were measured between the ketamine and the control groups at any assessment period. In Part II, synovitis was induced in the right stifle as described in Part I. Epidural injections at the lumbosacral space followed immediately. Analgesia was assessed at 2, 4, 6, 8, and 12 hours after the epidural injection and the induction of synovitis. Dogs that received ketamine had significantly lower NRS scores two hours after treatment (p < 0.05). NRS scores did not differ between the two treatment groups at any other evaluation. Vertical ground reaction forces did not significantly differ between treatment groups at any assessment period. Results of this study indicate that ketamine, when administered epidurally at a dose of 2 mg kg-1 after the induction of a chemical synovitis, does not provide a significant level of analgesia. However, administration of ketamine immediately before the induction of synovitis resulted in a significantly decreased subjective pain score at two hours, but not at later evaluation periods.
  • Thumbnail Image
    Changes in the Murine Nigrostriatal Pathway Following Pyrethroid and Organophosphate Insecticide Exposure: An Immunohistochemical Study
    Pittman, Julian Thomas (Virginia Tech, 2002-08-22)
    Parkinson's disease (PD) is a debilitating motor disorder that primarily afflicts older individuals (> 50yrs). Although its cause is unknown, many factors are thought to contribute to the disease. There is growing epidemiological evidence supporting a link between pesticide exposure and PD. The present immunohistochemical study was undertaken to characterize the role of insecticide exposure in the etiology of idiopathic PD. The insecticides selected for study were the pyrethroid permethrin (PE) and the organophosphate chlorpyrifos (CP), both of which possess properties that could damage or disrupt the nigrostriatal pathway, which is the principal neurodegenerative target in PD. The present study examined possible alteration of the amount of dopamine re-uptake transporter protein (DAT), within the striatum of the C57BL/6 mouse, using DAT antibodies, following low (0.8, 1.5 & 3.0 mg/kg) and high (200 mg/kg) doses of PE, respectively. Possible nigrostriatal terminal degeneration was examined using antibodies to tyrosine hydroxylase (TH), the rate-limiting enzyme in dopamine synthesis, following treatment with 50 mg/kg of CP alone or in combination with the high dose of PE. For both the high dose of PE alone and for the combined PE/CP treatment, glial fibrillary acidic protein (GFAP) antibodies were used to examine the possibility of non-degenerative tissue injury. Groups of matched treated/vehicle-control mice received three IP injections of the insecticide/dose of interest over a 2-week period. Counts of immunoreactive (IR) neuropil in the dorsolateral striatum were made from four pre-selected fields per striatal tissue section. Counts were compared between matched sections, processed on the same slide, from a treated mouse and its vehicle control. A mean difference score, across slides, for each treated/vehicle control pair was determined. All low dose PE groups showed a trend of decreased DAT IR neuropil, but only the 3.0mg/kg group showed a statistically significant reduction (p<.0078). The 200 mg/kg PE group showed a trend toward reduced TH IR neuropil that was not statistically significant, but a significant increase in GFAP IR (p = .048) was observed. No significant change in TH IR neuropil was observed for CP (50mg/kg) alone. A significant increase was observed for GFAP IR neuropil for the PE/CP (200/50 mg/kg) combination dose (p = .033). The combined insecticide treatment failed, however, to produce a significant change in TH IR within the striatum, compared to vehicle controls. These data suggest that the significant increases in GFAP IR neuropil, in the striatum, reflect some form of tissue insult, following exposure to a high dose of PE, or PE/CP in combination, that is insufficient to induce degeneration of dopaminergic terminals within the temporal interval investigated. Although such damage may be sufficient to account for previously reported decreases in maximal dopamine uptake observed with high doses of these compounds, the DAT IR data appear to indicate that this damage is unlikely to be a change in the amount of DAT in these high dose conditions. The decreases in striatal DAT IR neuropil observed for low doses of PE suggest an alteration in the normal integrity of the nigrostriatal pathway and in the route by which environmental toxins may enter dopaminergic neurons.
  • Thumbnail Image
    Congenital infection of mice with toxoplasma gondii induces minimal change in behavior and no change in neurotransmitter concentrations
    Goodwin, David G.; Hrubec, Terry C.; Klein, Bradley G.; Strobl, Jeannine S.; Werre, Stephen R.; Han, Qian; Zajac, Anne M.; Lindsay, David S. (American Society of Parasitology, 2012-08-01)
    We examined the effect of maternal Toxoplasma gondii infection on behavior and the neurotransmitter concentrations of congenitally infected CD-I mice at 4 and 8 wk of age when latent tissue cysts would be present in their brains. Because of sex-associated behavioral changes that develop during aging, infected female mice were compared with control females and infected male mice were compared with control males. Only the short memory behavior (distance between goal box and first hole investigated) of male mice congenitally infected with T. gondii was significantly different (P < 0.05) from that of uninfected control males at both 4 and 8 wk by using the Barnes maze test. The other parameters examined in the latter test, i.e., functional observational battery tests, virtual cliff, visual placement, and activity tests, were not significantly different (P > 0.05) at 4 and 8 wk. Concentrations of neurotransmitters and their metabolites (dopamine; 3,4-dihydroxyphenylacetic acid; homovanillic acid; norepinephrine; epinephrine; 3-methoxy-4-hydroxyphenylglycol; serotonin; and 5-hydroxyindoleacetic acid) in the frontal cortex and striatum were not different (P > 0.05) between infected and control mice at 8 wk of age. The exact mechanism for the observed effect on short-term memory in male mice is not known, and further investigation may help elucidate the molecular mechanisms associated with the proposed link between behavioral changes and T gondil infection in animals. We were not able, however, to confirm the widely held belief that changes in neurotransmitters result from chronic T. gondii infection of the brain.
  • Thumbnail Image
    Cranial manipulation affects cholinergic pathway gene expression in aged rats
    Anandakrishnan, Ramu; Tobey, Hope; Nguyen, Steven; Sandoval, Osscar; Klein, Bradley G.; Costa, Blaise M. (De Gruyter, 2022-01-10)
    Context: Age-dependent dementia is a devastating disorder afflicting a growing older population. Although pharmacological agents improve symptoms of dementia, age-related comorbidities combined with adverse effects often outweigh their clinical benefits. Therefore, nonpharmacological therapies are being investigated as an alternative. In a previous pilot study, aged rats demonstrated improved spatial memory after osteopathic cranial manipulative medicine (OCMM) treatment. Objectives: In this continuation of the pilot study, we examine the effect of OCMM on gene expression to elicit possible explanations for the improvement in spatialmemory. Methods: OCMM was performed on six of 12 elderly rats every day for 7 days. Rats were then euthanized to obtain the brain tissue, from which RNA samples were extracted. RNA from three treated and three controls were of sufficient quality for sequencing. These samples were sequenced utilizing next-generation sequencing from Illumina NextSeq. The Cufflinks software suite was utilized to assemble transcriptomes and quantify the RNA expression level for each sample. Results: Transcriptome analysis revealed that OCMM significantly affected the expression of 36 genes in the neuronal pathway (false discovery rate [FDR] <0.004). The top five neuronal genes with the largest-fold change were part of the cholinergic neurotransmission mechanism, which is known to affect cognitive function. In addition, 39.9% of 426 significant differentially expressed (SDE) genes (FDR<0.004) have been previously implicated in neurological disorders. Overall, changes in SDE genes combined with their role in central nervous system signaling pathways suggest a connection to previously reported OCMM-induced behavioral and biochemical changes in aged rats. Conclusions: Results from this pilot study provide sufficient evidence to support a more extensive study with a larger sample size. Further investigation in this direction will provide a better understanding of the molecular mechanisms of OCMM and its potential in clinical applications. With clinical validation, OCMM could represent a much-needed low-risk adjunct treatment for age-related dementia including Alzheimer's disease.
  • Thumbnail Image
    DNA Sequence and Haplotype Variation Analyses of Circadian Clock Genes and Their Effects on Phenotypes in the Turkey, Meleagris gallopavo
    Adikari Mudiyanselage, Jayantha Bandara Adikari (Virginia Tech, 2012-12-04)
    Present study was planned to compare the phenotypic variation of performances traits among commercial (CC) and heritage varieties of turkeys. Information about heritage turkey varieties continues to be limited. In addition, the emerging turkey genome sequence provides a unique opportunity to understand the DNA sequence variation and its associations with performance traits. The turClock, turPer3, turCry1 and turCry2 genes were screened and evaluated for its association with their performance traits. As expected, CC turkeys were superior to heritage birds in performance for most of the traits evaluated. However, heritage turkeys showed better reproductive performances compared to CC turkeys. A total of 41 SNPs were identified from the genes that screened. The haplogroups in the turClock gene were significantly associated with body weight (BW) at 309 d of age, feed conversion ratio (FCR) for 34 - 68 d and 69 - 159 d, egg production and average egg weight (P " 0.05). The haplogroups developed from turPeriod-3 gene were significantly associated with BW at 231 d of age, average daily gain (ADG) for 160 - 231 d, FCR for 69 - 159 d and 160 - 231 d, egg production traits, semen quality traits and plasma melatonin concentration (P " 0.05). In the turCry1 gene, haplogroups were significantly associated with ADG for 35 - 68 d, FCR for 160 - 231 d and 34 - 231 d, egg production and ejaculate volume (P " 0.05). The haplogroups identified from turCry2 gene were significantly associated with BW at 34, 68 and 231 d of age, ADG for 160 - 231 d, FCR for 34 - 68 d, average egg weight (P " 0.05). These findings reveal that phenotypic variation observed in growth and reproductive parameters among turkeys could be used for selecting birds for future breeding programs. DNA sequence variations at the nucleotide and haplotype levels are associated with some of growth, reproductive parameters and plasma melatonin of turkeys. Thus DNA sequence variations that identified of the circadian genes may have some regulatory role in the molecular mechanism of the circadian clock which may affect the circadian rhythm of the animal.
  • Thumbnail Image
    The Effect of Organophosphate Exposure on Neocortical, Hippocampal and Striatal Monoamines: A Potential Substrate for Chronic Psychiatric, Cognitive and Motor Dysfunction
    Lewis, Mary Catherine (Virginia Tech, 2003-08-20)
    Depression and other mood disorders, as well as cognitive and motor dysfunction have been linked with changes in monoamine levels in the brain. Environmental acetylcholinesterase (AChE) inhibitors, such as organophosphate insecticides (OPs), have also been shown to induce these problems. This study investigated whether insecticide-induced AChE inhibition, induced by chlorpyrifos (CPS), may contribute to the types of forebrain monoaminergic alterations associated with psychiatric, cognitive and motor dysfunction. Increased synaptic ACh, resulting from CPS-induced AChE inhibition, may alter the synthesis or release of monoamines through prolonged action of ACh on monoaminergic neurons that contain ACh receptors. Adult, male Sprague-Dawley rats were subjected to a single subcutaneous dose of CPS or corn oil vehicle. Brains were rapidly removed and the frontal cortex, hippocampus and striatum were bilaterally dissected on ice. These three regions from one side were assayed for AChE activity, while those from the opposite side were processed for high performance liquid chromatography with electrochemical detection (HPLC-ED) analysis of monoamine neurotransmitters and their metabolites. In the initial, exploratory experiment, inhibition of AChE activity was 66.8% in the frontal cortex, 43.8% in the hippocampus and 46.9% in the striatum, 7 days after a 60mg/kg dose of CPS. No significant differences in concentration of monoamine neurochemicals were observed between vehicle control and CPS-treated groups in either the hippocampus or striatum. However, in the frontal cortex of the CPS-treated rats there was a significant increase in median dihydroxyphenylacetic acid (DOPAC) concentration (P=0.019) and a very strong statistical trend toward increased dopamine (DA) concentration (P=0.0506). The second experiment examined the time course of AChE inhibition produced by a higher dose (200mg/kg) of CPS and how monoamine levels changed in conjunction with this pattern of AChE inhibition. Percent inhibition of AChE activity in CPS-treated animals, at 4, 14 and 21 days post-exposure was 77.0%, 86.6% and 81.9% in the frontal cortex, 86.1%, 85.9% and 83.2% in the hippocampus and 90.1%, 89.8% and 85.5% in the striatum. No significant differences in monoamine neurochemicals were observed between vehicle control and CPS-treated groups in either the hippocampus or striatum. A statistical trend toward a decrease in serotonin (5-HT) was seen in the frontal cortex at 14 days (P=0.0753) following CPS exposure. A very consistent, yet non-significant pattern of an increase in monoamines at 4 days post-CPS was observed in all instances, except for 5-hydroxyindoleacetic acid (5-HIAA) in the striatum. Therefore, the final experiment employed a more powerful design to focus on monoamine levels during, or shortly after, the change in AChE activity that rapidly follows exposure to 200mg/kg CPS. This experiment also employed a behavioral analysis on the day of sacrifice to assess the presence or absence of clinical signs of toxicity associated with this dose. Of the 30 CPS-treated rats, only 1 animal displayed a single behavioral sign of cholinergic poisoning. Percent inhibition of AChE activity at 2 and 4 days after treatment was 81.4% and 79.4% in the frontal cortex, 53.4% and 83.5% in the hippocampus, and 80.5% and 87.8% in the striatum. No significant changes in monoamine neurochemicals were observed between vehicle control and CPS-treated groups in either the frontal cortex or hippocampus. However, a significant increase in DOPAC (P=0.0285) in the striatum, 2 days after CPS treatment, was observed. In addition, a strong statistical trend toward decreased striatal 5-HT (P=0.0645) was reported 4 days after CPS treatment. The only significant correlation between AChE activity and monoamine concentration was observed for 5-HIAA in the striatum of CPS-treated, 2 day survivors (P=0.0445). However, it was of low magnitude (r=0.525, r2=0.276). CPS has a limited capacity to produce changes in monoamine neurotransmitters and/or their metabolites in the frontal cortex and striatum of the mammalian brain. These changes are primarily seen in the dopaminergic system. Alterations of monoamines do not appear to be strongly associated with incident levels of AChE inhibition. The biological implication of the limited OP induced changes in central monoamines remains significant, as changes in monoamines in the CNS nervous system have been linked to psychiatric, cognitive and motor dysfunction.
  • Thumbnail Image
    Effects of ammonium perchlorate exposure on the thyroid function and the expression of thyroid-responsive genes in Japanese quail embryos and post hatch chicks
    Chen, Yu (Virginia Tech, 2008-04-28)
    Perchlorate ion interferes with thyroid function by competitively inhibiting the sodium-iodide symporter, thus blocking iodide uptake into the thyroid gland. In this study, the effect of perchlorate exposure on thyroid function and thyroid-responsive gene expression were examined in (1) embryos from eggs laid by perchlorate-treated Japanese quail hens and (2) perchlorate-treated young Japanese quail. I hypothesized that perchlorate exposure would decrease thyroid function and that the consequent hypothyroidism would alter the expression of thyroid sensitive genes. Laying Japanese quail hens were treated with 2000 mg/l and 4000 mg/l ammonium perchlorate in drinking water. Eggs from these hens were incubated. Embryos, exposed to perchlorate in the egg, were sacrificed at day 14 of the 16.5 day incubation period. Japanese quail chicks, 4-5 days old, were treated with 2000 mg/l ammonium perchlorate in drinking water for 2 and 7.5 weeks. Thyroid status was evaluated by measuring plasma thyroid hormone concentrations, thyroid gland weight and thyroidal thyroid hormone storage. Expression of thyroid-responsive genes was evaluated by measuring the mRNA levels of Type 2 deiodinase (D2) in the brain and liver, RC3/neurogranin mRNA level in the brain and Spot 14 mRNA level in the liver. Maternal perchlorate exposure led to embryonic hypothyroidism, demonstrated by thyroid hypertrophy and very low embryonic thyroidal TH storage. Embryonic hypothyroidism decreased body growth and increased D2 mRNA level in the liver (a presumed compensatory response to hypothyroidism) but did not affect the mRNA levels of D2 and RC3 in the brain. Spot 14 mRNA was not detected in embryonic liver. In the second part of the study, quail chicks showed early signs of hypothyroidism after two weeks of 2000 mg/l ammonium perchlorate exposure; plasma concentration and thyroid gland stores of both T4 and T3 were significantly decreased. After 7.5 weeks of perchlorate exposure, all thyroid variables measured indicated that the chicks had become overtly hypothyroid. D2 mRNA level was increased, a compensatory response to hypothyroidism, and spot 14 mRNA level was decreased, a substrate-driven response in the liver of quail chicks after two weeks of perchlorate exposure. However, no difference was observed in the mRNA levels of D2 and spot 14 in the liver after 7.5 weeks of perchlorate exposure, suggesting there was some adaptation to the hypothyroid condition. The mRNA level of D2 and RC3 in the brain was not affected by perchlorate-induced hypothyroidism in quail chicks after either 2 or 7.5 weeks of perchlorate exposure. As in the embryos, this suggests the brain of chicks was "protected" from the hypothyroid body conditions.
  • Thumbnail Image
    The Effects of Neuropathy-Inducing Organophasphate Esters om Chick Dorsal Root Gangli Cell Cultures
    Massicotte, Christiane (Virginia Tech, 2001-09-09)
    Cultures of dorsal root ganglia (DRG) can achieve neuronal maturation with axons, making them useful for neurobiological studies. They have not, however, previously been used to investigate subcellular events that occur following exposure to neuropathy-inducing organophosphorus (OP) esters. Recent studies in other systems demonstrated alterations of ATP concentrations and changes in mitochondrial transmembrane potential (DYm) following exposure to neuropathy-inducing OP compounds, suggesting that mitochondrial dysfunction occurs. The present dissertation proposed an investigation using chick embryo DRG cultures to explore early mechanisms associated with exposure to these toxicants. This approach uses an in vitro neuronal system from the species that provides the animal model for OP-induced delayed neuropathy (OPIDN). DRG were obtained from 9-10 day old chick embryos, and grown for 14 days in minimal essential media (MEM) supplemented with bovine and human placental sera and growth factors. Cultures were then treated with 1 mM OP compounds, or the DMSO vehicle control. OP compounds used were phenylsaligenin phosphate (PSP) and mipafox, which readily elicit OPIDN in hens, and paraoxon, which does not cause OPIDN. Confocal microscopic evaluation of neuronal populations treated with PSP and mipafox showed opening of mitochondrial permeability transition (MPT) pores, and significantly lower mitochondrial tetramethylrhodamine fluorescence, suggesting alteration of mitochondrial structure and function. This supports our conclusion that mitochondria are a target for neuropathy-inducing OP compounds by inducing mitochondrial permeability transition. For further evaluation of mitochondrial function, mitochondrial respiratory chain reactions were measured. In situ evaluation of ATP production measured by bioluminescence assay showed decreased ATP concentrations in neurons treated with PSP and mipafox, but not paraoxon. This low energy state was present in several levels of the mitochondrial respiratory chain, including complexes I, III and IV, although complex I was the most severely affected. For morphological studies, the media containing the aforementioned toxicants was removed after 12 hours, and cultures maintained for 4 to 7 days post-exposure. Morphometric analysis of neurites in DRG was performed by inverted microscopy, using a system that was entirely computerized. Morphometric estimation of neurites treated with mipafox or PSP but not with paraoxon suggested that reversible axonal swelling at day 4 post-exposure had reversed by 7 days post-challenge. Ultrastructural alterations were described by electron microscopy. Damage to neurons was more severe following exposure to PSP and mipafox, with mitochondrial swelling and rarefaction of microtubules and neurofilaments observed within the cytoplasm. This study supports others that suggested mitochondria are a primary target for neuropathy-inducing OP compounds. We suggest that mitochondrial permeability transition (MPT) induce abrupt changes in mitochondrial membrane potentials, altering the proton gradient across the mitochondria membrane, decreasing ATP production within the cell. In addition, reduction in ATP production can be related to specific-complex alteration of the mitochondria respiratory chain following neuropathy-inducing OP compounds. The profound ATP depletion and the induction of MPT can induce the release of apoptotic factors and intramitochondrial ions, leading to axonal damage observed later in the course of OPIDN. This study provides evidence that chick DRG cell cultures are an excellent model to study early structural and functional features of OPIDN. It is likely that the alteration in energy lead to ultrastructural defects in these cells. These early events can contribute to alteration in neuronal ATP production previously reported in OPIDN. Cultures of dorsal root ganglia (DRG) can achieve neuronal maturation with axons, making them useful for neurobiological studies. They have not, however, previously been used to investigate subcellular events that occur following exposure to neuropathy-inducing organophosphorus (OP) esters. Recent studies in other systems demonstrated alterations of ATP concentrations and changes in mitochondrial transmembrane potential (DYm) following exposure to neuropathy-inducing OP compounds, suggesting that mitochondrial dysfunction occurs. The present dissertation proposed an investigation using chick embryo DRG cultures to explore early mechanisms associated with exposure to these toxicants. This approach uses an in vitro neuronal system from the species that provides the animal model for OP-induced delayed neuropathy (OPIDN). DRG were obtained from 9-10 day old chick embryos, and grown for 14 days in minimal essential media (MEM) supplemented with bovine and human placental sera and growth factors. Cultures were then treated with 1 mM OP compounds, or the DMSO vehicle control. OP compounds used were phenylsaligenin phosphate (PSP) and mipafox, which readily elicit OPIDN in hens, and paraoxon, which does not cause OPIDN. Confocal microscopic evaluation of neuronal populations treated with PSP and mipafox showed opening of mitochondrial permeability transition (MPT) pores, and significantly lower mitochondrial tetramethylrhodamine fluorescence, suggesting alteration of mitochondrial structure and function. This supports our conclusion that mitochondria are a target for neuropathy-inducing OP compounds by inducing mitochondrial permeability transition. For further evaluation of mitochondrial function, mitochondrial respiratory chain reactions were measured. In situ evaluation of ATP production measured by bioluminescence assay showed decreased ATP concentrations in neurons treated with PSP and mipafox, but not paraoxon. This low energy state was present in several levels of the mitochondrial respiratory chain, including complexes I, III and IV, although complex I was the most severely affected. For morphological studies, the media containing the aforementioned toxicants was removed after 12 hours, and cultures maintained for 4 to 7 days post-exposure. Morphometric analysis of neurites in DRG was performed by inverted microscopy, using a system that was entirely computerized. Morphometric estimation of neurites treated with mipafox or PSP but not with paraoxon suggested that reversible axonal swelling at day 4 post-exposure had reversed by 7 days post-challenge. Ultrastructural alterations were described by electron microscopy. Damage to neurons was more severe following exposure to PSP and mipafox, with mitochondrial swelling and rarefaction of microtubules and neurofilaments observed within the cytoplasm. This study supports others that suggested mitochondria are a primary target for neuropathy-inducing OP compounds. We suggest that mitochondrial permeability transition (MPT) induce abrupt changes in mitochondrial membrane potentials, altering the proton gradient across the mitochondria membrane, decreasing ATP production within the cell. In addition, reduction in ATP production can be related to specific-complex alteration of the mitochondria respiratory chain following neuropathy-inducing OP compounds. The profound ATP depletion and the induction of MPT can induce the release of apoptotic factors and intramitochondrial ions, leading to axonal damage observed later in the course of OPIDN. This study provides evidence that chick DRG cell cultures are an excellent model to study early structural and functional features of OPIDN. It is likely that the alteration in energy lead to ultrastructural defects in these cells. These early events can contribute to alteration in neuronal ATP production previously reported in OPIDN.
  • Thumbnail Image
    Evaluation of the Role of Astrocyte Glutamate Transport and of Synaptic NMDA Receptor Subtype Representation in the Pathogenesis of PTSD
    Cotrone, Thomas Steven (Virginia Tech, 2017-06-22)
    Post-traumatic stress disorder (PTSD) is a psychological disorder that can cause great social/economic hardship. Progress towards treating PTSD has been slow due to a lack of understanding of its pathogenesis. This dissertation aimed to address this issue by investigating the involvement of the astrocytic glutamate reuptake transporter, GLT-1, and regional differences in expression of NMDA receptor subtypes in the development of a rat model of PTSD. We hypothesized that impaired astrocytic glutamate reuptake inhibits long-term memory processes, and that concurrent presence of glucocorticoids (GCs) during situational trauma selectively inhibits fear extinction memory processes in the prefrontal cortex, but not of conditioned fear memory processes in the amygdala, due to differences between these brain regions in expression of NMDA receptor subtypes. The effect of GLT-1 manipulation was studied in vivo. Utilizing the Single Prolonged Stress (SPS) model of PTSD, rats were either exposed to SPS or not. Within these groups, rats were administered a saline sham, a GLT-1 facilitator (ceftriaxone (CEF)), or a GLT-1 inhibitor (dihydrokainic acid (DHK)). Using Classical Fear Conditioning (CFC) and Fear Extinction (EXT) paradigms, retention of fear extinction memories was measured to determine the effect of GLT-1 manipulation on SPS-induced behavior (i.e., impaired fear extinction retention). From the brain of each rat, the amygdala, hippocampus, and prefrontal cortex (PFC) were collected and expression of GLT-1, p-CREB (a molecular indicator of long-term memory), and glucocorticoid receptor (GR, a molecular indicator of a PTSD-like state) were quantified. Analysis of the behavioral data showed that SPS exposure alone reduced the retention of extinction memories, but CEF and DHK both eliminated this effect. Analysis of the brain tissues revealed that SPS induced an increase in GR expression in the hippocampus. SPS also increased GLT-1 expression, but not p-CREB, in the PFC and amygdala. To evaluate the involvement of regional differences in NMDA receptor subtype expression ex vivo, tissue sections of amygdala, hippocampus, and PFC were taken from SPS and non-SPS exposed rats. Synaptic transmission was stimulated in these tissues using bicuculline in the presence of glucocorticoids, NVP-AA077 (a NR2A NMDA receptor subtype inhibitor), or Ro-25 (a NR2B NMDA receptor subtype inhibitor). P-CREB was measured in the tissues treated with GCs to determine if GCs exert greater inhibition of long-term memory in the PFC (a region reported to express high NR2A) than in the amygdala (a region reported to express high NR2B). P-CREB was also measured in the tissues treated with NVP or Ro-25 to determine if these reported receptor profile differences could be demonstrated, and if they changed following SPS exposure. Contrary to the stated hypothesis, analysis of non-SPS exposed rats revealed that GCs, NVP, and Ro-25 decreased p-CREB in all three regions with no differences between regions. However, in the SPS exposed group, p-CREB was not decreased in PFC and hippocampal tissues treated with GCs, amygdalar and PFC tissues treated with NVP, and PFC tissue treated with Ro-25. Overall, the results of the in vivo experiment did not convincingly demonstrate a role of glutamate spill-over in the pathogenesis of PTSD, but did show that modulation of glutamate reuptake can mitigate some of the behavioral consequences of exposure to situational trauma. The results of the ex vivo experiment did not reveal evidence that regional differences in NMDA receptor profiles exist across the three regions analyzed, nor did they show that GCs exert a region specific inhibition of long-term memory formation. However, it was demonstrated that SPS may affect long-term memory by altering expression of synaptic NMDA receptors. This study provides evidence that glial cells may play a role in the pathogenesis of PTSD, and thus may serve as targets for future therapy.
  • Thumbnail Image
    Experimental and simulation-based assessment of the human postural response to sagittal plane perturbations with localized muscle fatigue and aging
    Davidson, Bradley (Virginia Tech, 2007-10-12)
    Falls from heights (FFH) are one of the leading causes of fatalities in skilled labor divisions such as construction, mining, agriculture/forestry, and manufacturing. Previous research has established that localized muscle fatigue (LMF) increases center of mass (COM)- and center of pressure (COP)-based measures of quiet stance. This is important because these increases have been linked to elevated risk of falls, and workers in the construction industry frequently engage in fatiguing activities while working at heights. In addition, the rate of fatality due to an occupational fall increases exponentially with age. Improved methods of fall prevention may be obtained through increased understanding of factors that have a deleterious effect on balance and postural control such as LMF and aging. An initial study was conducted to investigate the effects of LMF and aging on balance recovery from a postural perturbation without stepping. Sagittal plane postural perturbations were administered to young and older groups of participants before and after exercises to fatigue the lumbar extensors or ankle plantar flexors. Measures of balance recovery were based on the COM and COP trajectories and the maximum perturbation that could be withstood without stepping. Balance recovery measures were consistent with an LMF-induced decrement to recover from perturbations without stepping. Aging was also associated with an impaired ability to recover from the perturbations. The second study in the series investigated the effects of aging and LMF on the neural control of upright stance during small postural perturbations. Small magnitude postural perturbations were administered to young and older groups before and after fatiguing exercises. A single degree of freedom (DOF) model of the human body was developed that accurately simulated the experimentally collected kinematics during recovery from the perturbations. The model was controlled by invariant feedback gains that operated on the time-delayed kinematics. Feedback gains and time-delay were optimized for each participant, and a novel delay margin analysis was performed to assess system robustness toward instability. Results indicated that older individuals had a longer "effective" time-delay and exhibited greater reliance on afferent velocity information. No changes in feedback controller gains, time-delay, or delay margins were found with LMF in either age group. The final study investigated the use of a nonlinear controller to simulate responses to large magnitude postural perturbations. A three DOF model of the human body was developed and controlled with the state-dependent Riccati equation (SDRE). Parameters of the SDRE were optimized to fit the experimentally recorded kinematics. Unlike other forms of nonlinear control, the SDRE provides meaningful parameters for interpretation in the system identification. The SDRE approach was successful at stabilizing the dynamical system; however, accurate results were not obtained. Reasons for these errors are discussed, and an alternative formulation to the time-delayed optimal control problem using Roesser state space equations is presented.
  • Thumbnail Image
    A glutamate concentration-biased allosteric modulator potentiates NMDA-induced ion influx in neurons
    Costa, Blaise M.; Kwapisz, Lina Cortes; Mehrkens, Brittney; Bledsoe, Douglas N.; Vacca, Bryanna N.; Johnston, Tullia V.; Razzaq, Rehan; Manickam, Dhanasekaran; Klein, Bradley G. (Wiley, 2021-10-01)
    Precisely controlled synaptic glutamate concentration is essential for the normal function of the N-methyl D-aspartate (NMDA) receptors. Atypical fluctuations in synaptic glutamate homeostasis lead to aberrant NMDA receptor activity that results in the pathogenesis of neurological and psychiatric disorders. Therefore, glutamate concentration-dependent NMDA receptor modulators would be clinically useful agents with fewer on-target adverse effects. In the present study, we have characterized a novel compound (CNS4) that potentiates NMDA receptor currents based on glutamate concentration. This compound alters glutamate potency and exhibits no voltage-dependent effect. Patch-clamp electrophysiology recordings confirmed agonist concentration-dependent changes in maximum inducible currents. Dynamic Ca2+ and Na+ imaging assays using rat brain cortical, striatal and cerebellar neurons revealed CNS4 potentiated ion influx through native NMDA receptor activity. Overall, CNS4 is novel in chemical structure, mechanism of action and agonist concentration-biased allosteric modulatory effect. This compound or its future analogs will serve as useful candidates to develop drug-like compounds for the treatment of treatment-resistant schizophrenia and major depression disorders associated with hypoglutamatergic neurotransmission.
  • Thumbnail Image
    Insecticide-Mediated Neurochemical and Behavioral Changes as Possible Predisposing Environmental Factors in Idiopathic Parkinson's Disease
    Kirby, Michael L. Jr. (Virginia Tech, 1998-04-27)
    Epidemiological studies implicate pesticide exposure as a possible etiologic factor in idiopathic Parkinson's Disease, which results from degeneration of nigrostriatal neurons, along with reduced levels of the neurotransmitter, dopamine. Behavioral and neurochemical analyses in C57BL6 mice were performed following a subchronic dosing regime with the organochlorine insecticide heptachlor or the pyrethroid deltamethrin. Results were compared to those induced by the established parkinsonian neurotoxicant, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). At the end of the treatment period, mice were assessed for effects on behavior, as well as levels of striatal dopamine, nerve terminal respiration, and synaptosomal dopamine transport. The primary behavioral effect of deltamethrin was incoordination, while heptachlor caused hyperexcitability and increased locomotion. The major neurochemical effect observed for both compounds was upregulation of the presynaptic dopamine transporter (DAT) by 70% and 100% for deltamethrin and heptachlor, respectively. The insecticides exerted only modest effects on striatal levels of dopamine and its metabolite, dihydroxyphenylacetic acid. However, doses of heptachlor higher than those which caused induction of DAT (e.g. greater than or equal to 25 mg/kg), when administered subchronically, were found to cause convulsions in some animals and caused marked, dose-dependent depression of basal striatal tissue respiration rates. No synergism was observed between the effects of insecticides and MPTP. Enhanced transport was thought to be a compensatory effect from increased release of transmitters by the insecticides, in vivo. Striatal dopamine, GABA and glutamate nerve terminals were differentially sensitive to the releasing effects of heptachlor compared to cortical serotonin terminals, and responded in the following rank order of sensitivity: dopamine > GABA > glutamate > serotonin. Additional experiments to characterize the mechanism(s) by which cyclodienes facilitate release of neurotransmitters in synaptosomes demonstrated a lack of distinct Ca²⁺ component and no involvement of retrograde DAT activity, suggesting that released label was of vesicular origin, but did not require Ca²⁺. Insecticidal toxicants, such as organochlorines and pyrethroids, which augment dopamine release and increase the maximal rate of dopamine uptake, may inundate the cytosol of nigrostriatal neurons with high concentrations of free dopamine, which has been shown by other researchers to induce apoptosis and may thereby contribute to the development of Parkinson's disease. Funding for this work was provided under grant number HHHREP 94-01 by the Hawaii Heptachlor Foundation, a non-profit organization. The Hawaii Heptachlor Foundation may be contacted at the following address: Ocean View Center PH#3, 707 Richards St., Honolulu, HI 96813.
  • Thumbnail Image
    Intracellular potassium depletion enhances apoptosis induced by staurosporine in cultured trigeminal satellite glial cells
    Bustamante, Hedie A.; Ehrich, Marion F.; Klein, Bradley G. (2021-06-30)
    Purpose Satellite glial cells (SGC) surrounding neurons in sensory ganglia can buffer extracellular potassium, regulating the excitability of injured neurons and possibly influencing a shift from acute to neuropathic pain. SGC apoptosis may be a key component in this process. This work evaluated induction or enhancement of apoptosis in cultured trigeminal SGC following changes in intracellular potassium [K]ic. Materials and methods We developed SGC primary cultures from rat trigeminal ganglia (TG). Purity of our cultures was confirmed using immunofluorescence and western blot analysis for the presence of the specific marker of SGC, glutamine synthetase (GS). SGC [K]ic was depleted using hypo-osmotic shock and 4 mM bumetanide plus 10 mM ouabain. [K]ic was measured using the K+ fluorescent indicator potassium benzofuran isophthalate (PBFI-AM). Results SGC tested positive for GS and hypo-osmotic shock induced a significant decrease in [K]ic at every evaluated time. Cells were then incubated for 5 h with either 2 mM staurosporine (STS) or 20 ng/ml of TNF-alpha and evaluated for early apoptosis and late apoptosis/necrosis by flow cytometry using annexin V and propidium iodide. A significant increase in early apoptosis, from 16 to 38%, was detected in SGC with depleted [K]ic after incubation with STS. In contrast, TNF-alpha did not increase early apoptosis in normal or [K]ic depleted SGC. Conclusion Hypo-osmotic shock induced a decrease in intracellular potassium in cultured trigeminal SGC and this enhanced apoptosis induced by STS that is associated with the mitochondrial pathway. These results suggest that K+ dysregulation may underlie apoptosis in trigeminal SGC.
  • Thumbnail Image
    Modeling and Monitoring of Otolith Organ Performance in US Navy Operating Environments
    McGrath, Elizabeth Ferreira (Virginia Tech, 2003-04-24)
    Previous mathematical modeling work has produced a transfer function that relates otoconial layer displacement to stimulus acceleration. Due to the complexity of this transfer function, time domain solutions may be obtained only through numerical methods. In the current work, several approximations are introduced to the transfer function that result in its simplification. This simplified version can be inverted to yield analytic time domain solutions. Results from a frequency response analysis of the simplified transfer function are compared with the same results from the complete transfer function, and with mammalian first-order neuron frequency response data. There is good agreement in the comparisons. Time domain solutions of the approximation are compared to numerical solutions of the full transfer function, and again there is a good match. System time constants are calculated from the simplified transfer function. A 2-D finite element model of a mammalian utricular macula is presented. Physical dimensions used in the model are taken from mammalian anatomical studies. Values for the material properties of the problem are not readily available; however, ranges are chosen to produce realistic physiologic behavior. Deflections predicted by this model show that a single value for hair bundle stiffness throughout the organ is inadequate for the organ to respond to the entire range of human acceleration perception. Therefore, it is necessary for a range of hair bundle stiffnesses to exist in each organ. Natural frequencies calculated in this model support previous studies on vestibular damage due to low frequency sound. Divers exposed to high-intensity underwater sound have experienced symptoms attributed to vestibular stimulation. An in-water video-oculography (VOG) system was developed to monitor divers' eye movements, particularly torsional, during exposure to varying underwater sound signals. The system included an underwater closed-circuit video camera with infrared lights attached to the diver's mask with an adjustable mounting bracket. The video image was sent to a surface control room for real-time and post-experiment processing. Six divers at 60 feet in open water received 15 minutes daily cumulative exposure of 240-320 Hertz underwater sound at 160 dB re 1 mPa for 10 days. No spontaneous primary position nystagmus, horizontal, vertical or torsional, was detected in any diver. This experiment was the first successful attempt to record and analyze eye movements underwater.
  • Thumbnail Image
    The Molecular Mechanisms of Organophosphorus Compound-induced Cytotoxicity
    Carlson, Kent Richard (Virginia Tech, 2000-05-19)
    Certain organophosphorus compounds have the ability to induce a delayed neuropathic condition in sensitive species termed organophosphorus compound-induced delayed neurotoxicity (OPIDN). Esteratic changes associated with OPIDN have been successfully modeled in vitro. The physical characteristics of lesion development in OPIDN including the mode of nerve cell death, cytotoxic initiator and effector molecules, and cytoskeletal involvement have received little in vitro investigation. This dissertation evaluated the mode of cell death (apoptosis versus oncotic-necrosis), and cell cycle, cytoskeletal, nuclear, and mitochondrial alterations induced by OP compounds in SH-SY5Y cultures, an in vitro human neuroblastoma model. The distribution of in vivo neural degeneration in white Leghorn hen models was also assessed as a prelude to validating the mode of OP compound-induced in vivo neural cell death. These endpoints were evaluated by utilizing flow cytometry, spectrophotometry, gel electrophoresis, immunohistochemistry, light, and electron microscopy. Initial data gathered on culture parameters revealed that the mitotic status, basal rates of cell death, and total culture density were dependent on the condition of the media and the initial seeding density. Subsequent in vitro investigations used standardized culture conditions with OP compounds (diisopropylphosphorofluoridate (DFP), paraoxon, parathion, phenyl saligenin phosphate (PSP), tri-ortho-tolyl phosphate (TOTP), and triphenyl phosphite (TPPi); 1uM - 1mM). These studies revealed that OP compounds altered the cell cycle phase, decreased the amount of intracellular f-actin, altered the mitochondrial membrane potential, and induced caspase-3 activation and nuclear partitioning characteristic of apoptosis. The amount of change in these parameters was strongly dependent on the OP compound, the length of incubation time, and the presence of modulators of cytotoxicity such as phenylmethylsulfonyl fluoride (PMSF), carbachol, Ac-DEVD-CHO, Ac-IETD-CHO, and cyclosporin A. Preliminary in vivo experiments designed to validate in vitro results revealed neural degeneration involving fibers, terminals, and cell soma in spinal cord and brain tissue of PSP- and TPPi- exposed hens. The distribution and magnitude of these changes were contingent on the OP compound and length of time post-exposure. Subsequent experiments designed to evaluate the mode of cell death in these tissues revealed little evidence of either necrosis or apoptosis. These results, therefore, did not support or refute in vitro observations. Many OP compound-induced subcellular alterations have been demonstrated in our in vitro SH-SY5Y neuroblastoma model. Even though the mode of cell death observed in SH-SY5Y cells was not validated in in vivo experiments, in vitro observations nonetheless provide stimulating areas to further research the mechanisms of OPIDN and OP compound-induced cell death.
  • Thumbnail Image
    The Murine Brain Slice as a Model for Investigation of Environmental Toxin Involvement in the Etiology of Parkinson's Disease
    Freeborn, Ethan Ray (Virginia Tech, 1999-05-10)
    Epidemiological and analytical studies have suggested that environmental exposure to neurotoxic insecticides may exist as a factor in the etiology of Parkinson's Disease (PD). This study has focused on two insecticides, dieldrin and heptachlor epoxide, members of the cyclodiene class of insecticides. The cyclodienes are environmentally persistent, and brain residues of these compounds are correlated with the occurrence of PD. Cyclodiene mode of action has been attributed to two mechanisms: 1) facilitation of neurotransmitter release (with specificity for release of dopamine) and 2) antagonism of the inhibitory neurotransmitter, GABA. In order to assess the relative contributions of these two mechanisms leading to toxicity, eletrophysiological studies were undertaken in murine striatal slices. Extracellular recordings of spontaneous nerve discharge were used to compare the effects of the cyclodienes and the prototypical GABA antagonist, picrotoxinin, upon striatal neurons. At low micromolar concentrations of cyclodiene, depression of firing, consistent with dopamine release and not GABA antagonism, was seen. Alternatively, application of the prototypical GABA antagonist, picrotoxinin, produced excitation in slices. Additionally, the inhibitory action of dieldrin was blocked by a dopamine receptor (D1) antagonist, fluphenazine, verifying that cyclodiene-released dopamine was responsible for the observed depression of striatal neurons. These results suggest that the ability of these cyclodienes to evoke neurotransmitter release may significantly contribute to the neurotoxicity of these cyclodienes in vivo. In light of this data, the neurotoxic potential of the cyclodiene insecticides must be reassessed, particularly within the scope of PD.
  • Thumbnail Image
    Neurochemical Effects of Concurrent Exposure to Repeated Stress and Chlorpyrifos on the Central Nervous System
    Pung, Thitiya (Virginia Tech, 2004-09-14)
    Repeated stress has been reported to cause reversible impairment to the hippocampus. Glutamatergic and cholinergic systems were proposed to be involved in responses seen after exposure to stress and cholinesterase inhibitors. Effects of concurrent exposure to repeated stress and chlorpyrifos (CPF) on concentrations of excitatory amino acids, activities of cholinergic enzymes, and maximum binding density (Bmax) and equilibrium dissociation rate constant (Kd) of NMDA and total muscarinic receptors were studied in Long-Evans rats. The study was divided into 4 experiments. The first experiment was to find the dose of CPF to use for studies on the interaction of stress and CPF. From the results obtained, 60% of the maximum tolerated dose was chosen. An experiment to determine effects of repeated stress and CPF on cholinergic enzymes and glutamate included groups of rats (n=7-8) that were handled 5 days/week; restrained 1 hour/day for 5 days/week; swum 30 minutes for 1 day/week; or restrained 4 days/week and swum for 1 day/week, for 28 days. On day 24, each group was injected either with corn oil or CPF 160 mg/kg sc 4 hours after restraint. On day 28, blood samples were collected for acetylcholinesterase (AChE) activity. Brains were dissected into hippocampus (HP) and cerebral cortex (CC) to determine activities of acetylcholinesterase (AChE), carboxylesterase (Cbxy), and choline acetyltransferase (ChAT), and glutamate and aspartate concentrations. CPF inhibited AChE activity in blood, CC and HP, but stress did not affect AChE activity. Repeated restraint with swim reduced Cbxy and CPF inhibited Cbxy. Restraint with swim had a statistical trend to increase concentrations of glutamate in the HP more than swim alone (p = 0.064); but CPF had no effect on glutamate in the HP. CPF decreased concentrations of elevated aspartate in the HP of rats that were restrained and swum. The results suggested that restraint with swim indirectly elevated acetylcholine in the CC, and tended to increase glutamate in the HP. The experiment designed to study the effects of concurrent exposure to stress and CPF on NMDA and total muscarinic receptors was designed similar to the previous study, except that endpoints were Bmax and Kd of NMDA and total muscarinic receptors in the HP and CC, and NMDA receptors in the hypothalamus (HT). Restrained rats had higher Kd of NMDA receptors in the HP than control and restrained with swim rats; however, Bmax was similar. CPF deceased Bmax and Kd of total muscarinic receptors in the CC of swum rats (237.64 ± 17.36 fmol/mg protein, 0.216 ± 0.023 nM) and CPF also decreased Bmax of total muscarinic receptors in the CC of restrained rats (229.08 ± 17.36 fmol/mg protein). There were no effects of stress, CPF, or interactions of stress and CPF on NMDA receptors in the CC or on total muscarinic receptors in the HP. In summary, CPF was capable of modulation of total muscarinic receptors of swum and restrained rats, suggesting that cholinergic transmission in the CC for cognition, sensory and motor activity may be modified. Furthermore, we examined effects of stress and CPF on concentrations of monoamines. Swim stress and CPF individually decreased concentrations of norepinephrine in the HP, whereas swim and restraint with swim decreased concentrations of norepinephrine but increased concentrations of DOPAC in the HT. Swim stress increased concentrations of dopamine in the HT more than control or restraint. CPF did not alter concentrations of norepinephrine, dopamine, or DOPAC in the HT. The interactions of repeated stress and CPF on serotonin approached significance in the HP (p = 0.06) and HT (p = 0.08). CPF increased serotonin concentrations in rats that were handled and restrained but not swum. CPF reduced the elevated concentrations of serotonin in restrained rats and restrained with swim rats (p < 0.05). Swim and restraint with swim were potential stress models that altered noradrenergic, dopaminergic, and serotonergic responses in the HT. In summary, repeated stressors had effects on glutamatergic, cholinergic, and monoamine systems. CPF had effects on cholinergic and monoamine systems but the interactions between stress and CPF were few.
  • Thumbnail Image
    The Neurotoxicity of Insecticides to Striatal Dopaminergic Pathway
    Kou, Jinghong (Virginia Tech, 2005-11-18)
    Parkinson's disease (PD) is an age-related neurodegenerative disease, which is characterized by severe loss of dopaminergic neurons in the substantia nigra pars compacta (SNc) and consequent dopamine depletion in its projecting area. In this dissertation, I evaluated the neurotoxicity of several classes of insecticides/drugs/neurotoxins to the striatal dopaminergic pathway and their potential relationship to Parkinsonism in the C57BL/6 mouse model, using biochemical and molecular biology methods. In the first objective, I investigated the neurotoxicity in striatal dopaminergic pathways following co-application of permethrin (PM), chlorpyrifos (CPF) and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). The study was done because pyrethroid and organophosphorus compounds are widely used insecticides and they have been implicated in Gulf War Syndrome. We found that short-term, high-dose exposure to PM or CPF had no significant effects on the expression of dopamine transporter (DAT), tyrosine hydroxylase (TH), or α-synuclein protein in striatal nerve terminals, but the insecticides slightly enhanced the neurotoxicity of MPTP in C57BL/6 mice at 28 days post-treatment. This finding indicates a slowly developing neurotoxicity may occur after termination of high-dose exposure. Long-term, low-dose exposure to PM did not show significant neurotoxicity to striatal dopaminergic pathways when given alone, nor did this injection of PM enhance the neutotoxicity of MPTP in C57BL/6 mice. In addition, experiments with pure cis or trans isomers of permethrin showed that both cis and trans isomers contributed equally to the neurotoxicity of PM in the short-term high dose study. Previous studies demonstrated a deficiency in mitochondrial function in PD, and a high density of K⁺ATP channels are present in substantia nigra, which play an important role in the maintenance of the membrane potential under metabolic stress. Therefore, in the second objective, I investigated the effect of K⁺ATP channel blockage on the neurotoxicity of mitochondrial-directed neurotoxins to striatal dopaminergic pathways. I found that mitochondrial inhibitors are potent releasers of preloaded dopamine from striatal nerve terminals, with the most potent compounds active in the nanomolar range. Co-application of the K⁺ATP channel blocker glibenclamide selectively increased the dopamine-releasing effect by complex I inhibitors in vitro, and potentiated the neurotoxicity of MPTP (a complex I inhibitor) on DAT and TH expression, in vivo. Mechanistic studies demonstrated that mitochondrial inhibitor-induced dopamine release is Ca²⁺-dependent. In addition, the selectivity of glibenclamide is not correlated to ATP depletion, but associated with the generation of excessive reactive oxygen species at the site of complex I. In the third objective, I conducted comparative studies on the mode of action of rotenone-/reserpine-/tetrabenzaine (TBZ)-induced depletion, in vitro, as these three compounds share some similarities in their chemical structures. I found that rotenone, reserpine and TBZ selectively released preloaded dopamine and serotonin (5-HT), with the rank order as rotenone>reserpine>TBZ. Mechanistic studies demonstrated more than one mechanism was involved in both rotenone- and reserpine-induced neurotransmitter release. Ca²⁺-stimulated vesicular release and neurotransmitter transporter-mediated release are the common mechanisms involved in rotenone- and reserpine-induced dopamine release. Overall, the insecticides/drugs/neurotoxins tested in the above experiments all exhibited some effect on the nigrastrital dopaminergic pathway, either alone or by enhancing the toxicity of other chemicals in combination treatment.
  • Thumbnail Image
    Pesticides and Pesticide Mixtures Induce Neurotoxicity: Potentiation of Apoptosis and Oxidative Stress
    Jia, Zhenquan (Virginia Tech, 2006-07-07)
    Several epidemiological studies have suggested a role for environmental chemicals in the etiology of neurodegenerative diseases such as Parkinson's disease and Alzheimer's disease. Endosulfan (an organochlorine) and zineb (zinc-ethylene-bis-dithiocarbamate) are used as pesticides on a variety of crops worldwide and pose potential health risks to humans and animals. Both endosulfan and zineb are known to affect nervous system. Because the dopaminergic system continues to develop postnatally, we hypothesized that developmental exposure to endosulfan or zineb alone or in combination would result in alteration of nigrostrial neurotransmitters and would render the nigrostrial dopamine system more susceptible to chemical challenge later in life. The objectives of this study were (1) to determine the effects of endosulfan and zineb individually and in combination on dopaminergic or cholinergic pathways in vivo, (2) to investigate the effects of exposure to endosulfan, zineb and their mixtures administered in early life (during brain development) on subsequent exposure to these pesticides on the dopaminergic and cholinergic systems, in vivo, (3) to investigate the mechanism(s) of induction of neuronal cell death caused by these pesticides using human neuroblastoma SH-SY5Y cells in culture, (4) to define the role of oxidative stress in pesticide-induced neuronal cell death in vitro. Male C57Bl/6 mice of 7-9 months old exposed to zineb (50 and 100 mg/kg), endosulfan (1.55, 3.1 and 6.2 mg/kg) and their mixtures every other day over a 2-week period exhibited higher levels of dopamine accumulation in the striatum. Both pesticide-treated groups displayed significantly lower norepinephrine levels in the striatum (Ï ≤ 0.05) than the controls. The developmental exposure to zineb, endosulfan and their combination enhanced the vulnerability to subsequent neurotoxic challenges occurring later in life. Thus, C57BL/6 mice exposed to zineb, endosulfan and their mixtures as juveniles (postnatal days 5 to 19) and re-exposed at 8 months of age showed a significant depletion of striatal dopamine, to 22%, 16%, and 35% of control, respectively. Acetylcholinesterase activity in the cerebral cortex was found to be significantly increased in all pesticide treated groups. Mice given mixtures of pesticides also showed significantly increased levels of normal and aggregated alpha-synuclein, a hallmark of neurodegenerative diseases such as Parkinson's disease and Alzheimer's disease. The results of these studies indicate that exposure to these pesticides as neonates and re-exposure as adults could result in neurochemical changes that did not reveal at adulthood when the exposure was at juvenile age only. We further investigated the mechanism(s) of activation of pesticide-induced neuronal cell death in vitro. The characteristic of cell death in SH-SY5Y human neuroblastoma cells was examined. These cells are known to retain catecholaminergic phenotype. Cells were exposed to endosulfan, zineb and mixtures of two pesticides, in concentrations ranging from 50 μM to 400 μM. These exposures caused both apoptotic and necrotic cell death in SH-SY5Y cells as evaluated by lactate dehydrogenase release, 7-aminoactinomycin-D and Annexin-V/PI assays. Exposure to mixtures of the pesticides enhanced both the early apoptosis and late apoptosis/necrosis compared to either chemical alone. Visual evaluation using DNA ladder assay and fluorescence Annexin V/PI assay confirmed the contribution of both apoptotic and necrotic events. Furthermore, endosulfan and zineb alone and in combination altered the caspase-3 activity indicating that both pesticides exposure exert their apoptotic effect via the caspase-3 pathway. Because there has been increasing evidence of the role of reactive oxygen species (ROS) and oxidative stress in pesticide-induced neuronal cell death (apoptosis and necrosis), the levels of ROS and antioxidant enzymes were examined. Cells treated with pesticides were found to enhance the generation of superoxide anion and hydrogen peroxide both in a dose- and time-dependent manner. Mixture of pesticides significantly enhanced the production of these reactive oxygen species compared to cells exposed to individual pesticide. Cells treated with pesticides showed a decrease in superoxide dismutase, glutathione peroxidase, and catalase levels. These pesticides also induced lipid peroxides (thiobarbituric acid reactive products) formation in SH-SY5Y cells. Furthermore, cells exposed to these pesticides were found to have increased in the expression of NFkappaB activity in the nucleus. These data support the hypothesis that oxidative stress was induced in neuronal cells by exposing to these pesticides in vitro. Taken together, the results of this study support the above hypothesis and suggest that the cytotoxicity of endosulfan and zineb and their combinations may, at least in part, be associated with the generation of ROS. Furthermore, mice exposed at early age and re-exposed at adulthood become more susceptible to alteration of neurotransmitter levels compared to mice exposed to these pesticides only as juveniles. These findings could add to the growing body of knowledge on the mechanism of pesticide-induced dopaminergic neuronal cell death and could hold tremendous implication for the future understanding of the possible involvement of environmental risk factors in the pathogenesis of Parkinson's disease.